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Chapter 4: Tour of the CellBIO100Fall 2007
THE MICROSCOPIC WORLD OF CELLSCells must be tiny for materials to move in and out of them and fast enough to meet the cells metabolic needs.
Organisms are eitherSingle-celled, such as most bacteria and protistsMulticelled, such as plants, animals, and most fungi.
Microscopes as Windows to CellsThe light microscope is used by many scientistsLight passes through the specimenLenses enlarge, or magnify, the image.Figure 4.2A(a) Light micrograph (LM) of a white blood cell (stained purple) surrounded by red blood cells
How We Study CellsLight Microscope:First cells observed by Robert Hooke in 1665 using a light microscope.Simple vs. Compound?
MagnificationAn increase in the specimens apparent sizeResolving powerThe ability of an optical instrument to show two objects as separate.
Cells were first discovered in 1665 by Robert HookeThe accumulation of scientific evidence led to the cell theory, p. 57All living things are composed of cellsAll cells form from previously existing cellsCells are the smallest units capable of carrying out the processes of life: ex. respiration, digestion, reproduction, growth, ingestion, etc.
The electron microscope (EM) uses a beam of electronsIt has a higher resolving power than the light microscope.
The electron microscope can magnify up to 100,000XSuch power reveals the diverse parts within a cell.Figure 4.3Unaided eyeLight microscopeElectron microscope
Metric Prefixes:Kilo=1000 so 10 Kcalories=10 000 calories= 10 C Hecto=100 Deka=10 Unit=1 ex. meter, liter, gram deci=0.1 centi=0.01 so 1 cm=10 mm milli=0.001
The scanning electron microscope (SEM) is used to study the detailed architecture of the surface of a cell.Figure 4.2B(b) Scanning electron micrograph (SEM) of a white blood cell
The transmission electron microscope (TEM) is useful for exploring the internal structure of a cell.
Figure 4.2C(c) Transmission electron micrograph (TEM) of a white blood cell
The Two Major Categories of CellsThe countless cells on earth fall into two categoriesProkaryotic cellsEukaryotic cells
Prokaryotic and eukaryotic cells differ in several respects.Figure 4.4Prokaryotic cellNucleoid regionEukaryotic cellNucleusOrganelles
Prokaryotic cellsAre smaller than eukaryotic cellsLack internal structures surrounded by membranesLack a nucleus.
Figure 4.5ProkaryoticflagellaNucleoid region (DNA)RibosomesPlasmamembraneCell wallCapsulePili
A Panoramic View of Eukaryotic CellsFigure 4.6A, p. 59CytoskeletonRibosomesCentrioleLysosomeFlagellumNot in mostplant cellsNucleusSmoothendoplasmicreticulum (ER)GolgiapparatusRoughendoplasmicreticulum (ER)MitochondrionPlasmamembrane
An idealized plant cell.Figure 4.6B, p. 59CytoskeletonMitochondrionNucleusRough endoplamsic reticulum (ER)RibosomesSmoothendoplasmicreticulum (ER)Golgi apparatusPlasmodesmataPlasmamembraneChloroplastCell wallCentralvacuoleNot in animal cells
The nucleus is an organelle which contains long fibers made of DNA molecules and associated proteins. Each fiber, known as chromatin, becomes a chromosomeHumans have 46 chromosomes in the nucleus of each and every cellAlso within the nucleus is the nucleolus which is a ball-like mass of fibers and granules which produces the component parts of ribosomes.
Ribosomes move through the pores of the nucleus then are responsible for protein synthesis. Some are associated with rough ER others remain suspended in the cytosol.
MEMBRANE STRUCTURE AND FUNCTIONThe plasma membrane separates the living cell from its nonliving surroundingsThe entire region of cell between the nucleus and plasma membrane is the cytoplasmCytoplasm consists of organelles surrounded by a liquid known as cytosol.
A Fluid Mosaic of Lipids and ProteinsThe membranes of cells are composed ofLipidsProteins.
The lipids belong to a special category called phospholipidsPhospholipids form a two-layered membrane, the phospholipid bilayer.Figure 4.7AHydrophilicheadHydrophobictailOutside cellCytoplasm(inside cell)(a) Phospholipid bilayer of membrane
Most membranes have specific proteins embedded in the phospholipid bilayer.
Figure 4.7BHydrophilicregion ofproteinPhospholipidbilayerHydrophobicregion of protein(b) Fluid mosaic model of membrane
Some functions of membrane proteins.Figure 4.8Fibers ofextracellularmatrixCytoskeletonCytoplasmAttachment tocytoskeleton andextracellularmatrixabCell signalingcdEnzymatic activityTransporteIntercellularjoiningfCell-cellrecognitionCytoplasm
Membrane phospholipids and proteins can drift about in the plane of the membraneThis behavior leads to the description of a membrane as a fluid mosaicMolecules can move freely within the membraneA diversity of proteins exists within the membrane.
Selective PermeabilityMembranes of the cell are selectively permeableThey allow some substances to cross more easily than othersThey block passage of some substances altogether.
The traffic of some substances can only occur through transport proteinsGlucose, for example, requires a transport protein to move it into the cell.
THE NUCLEUS AND RIBOSOMES:GENETIC CONTROL OF THE CELLThe nucleus is the manager of the cellGenes found on the chromosomes within the nucleus store information necessary to produce proteins.
Structure and Function of the NucleusThe nucleus is bordered by a double membrane called the nuclear envelopeIt contains chromatinIt contains a nucleolus.
Figure 4.9RibosomesChromaticNuclearenvelopeNucleolusPore
RibosomesRibosomes build all the cells proteins.
How DNA Controls the CellDNA controls the cell by transferring its coded information into RNAThe information in the RNA is used to make proteins.Figure 4.10Synthesis ofmRNA in thenucleus12Movement ofmRNA intocytoplasm vianuclear pore3Synthesis ofprotein in thecytoplasmDNAmRNANucleusCytoplasmmRNARibosomeProtein
THE ENDOMEMBRANE SYSTEM: MANUFACTURING AND DISTRIBUTING CELLULAR PRODUCTSMany of the membranous organelles in the cell belong to the endomembrane system.
The Endoplasmic ReticulumThe endoplasmic reticulum (ER)Produces an enormous variety of moleculesIs composed of smooth and rough ER.Figure 4.11NuclearenvelopeRibosomesRough ERSmooth ER
Rough ERAgain, the roughness of the rough ER is due to ribosomes that stud the outside of the ER membrane.
The functions of the rough ER includeProducing proteinsProducing new membrane.
After the rough ER synthesizes a molecule it packages the molecule into transport vesiclesFigure 4.12Transport vesiclebuds offRibosomeSecretoryprotein insidetransportvesicleProteinRough ERPolypeptide1234
Smooth ERThe smooth ER lacks the surface ribosomes of ER and produces lipids, including steroids.
The Golgi ApparatusWorks in partnership with the ERRefines, stores, and distributes the products of cells.Figure 4.13Transportvesiclefrom ERReceiving side ofGolgi apparatusGolgi apparatusNew vesicle formingTransport vesiclefrom the GolgiShipping side ofGolgi apparatusPlasma membrane
LysosomesA lysosome is a membrane-enclosed sacIt contains digestive enzymesThe enzymes break down macromolecules. So lysosomes are responsible for intracellular digestion.If its membrane were to break its contents would digest the cell
Lysosomes have several types of digestive functionsThey fuse with food vacuoles to digest the food.PlasmamembraneDigestive enzymesLysosomeFoodFood vacuoleDigestion(a) Lysosome digesting foodFigure 4.14a
They break down damaged organellesThey carry out the intracellular digestion.Figure 4.14b(b) Lysosome breaking down damaged organelleLysosomeDamagedorganelleDigestion
VacuolesVacuoles are membranous sacsTwo types are the contractile vacuoles of protists and the central vacuoles of plants.Figure 4.15ContractilevacuolesCentralvacuole(a) Contractile vacuoles in a protist(b) Central vacuole in a plant cell
A review of the endomembrane system.
Figure 4.16Rough ERTransportvesicle from ERGolgiapparatusSecretoryvesicle from GolgiSecretoryproteinVacuoleLysosomePlasma membrane
CHLOROPLASTS AND MITOCHONDRIA: ENERGY CONVERSIONCells require a constant energy supply to do all the work of life. Nuclei, chloroplasts, and mitochondria are organelles having double membranes.
CHLOROPLASTSChloroplasts are the sites of photosynthesis, the conversion of light energy to chemical energy.Figure 4.17Inner and outermembranes ofenvelopeSpace betweenmembranesStroma (fluid inchloroplast)Granum
MitochondriaMitochondria are the sites of cellular respiration, which involves the production of ATP from food molecules.Figure 4.18OutermembraneInnermembraneCristaeMatrixSpace betweenmembranes
ATP
THE CYTOSKELETON:CELL SHAPE AND MOVEMENTThe cytoskeleton is an infrastructure of the cell consisting of a network of fibers.
Maintaining Cell ShapeOne function of the cytoskeletonFigure 4.19AProvide mechanical support to the cell and maintain its shape.
The cytoskeleton can change the shape of a cellThis allows cells like amoebae to move.Figure 4.19B
Cilia and FlagellaCilia and flagella are motile appendages.
Flagella propel the cell in a whip-like motionCilia move in a coordinated back-and-forth motion.Figure 4.20A, B
Some cilia or flagella extend from nonmoving cellsThe human windpipe is lined with cilia.Figure 4.20C
CELL SURFACES:PROTECTION, SUPPORT, AND CELL-CELL INTERACTIONSMost cells secrete materials that are external to the plasma membrane.
Plant Cell Walls and Cell JunctionsPlant cells are encased by cell wallsFigure 4.21These provide support for the plant cells.Walls of two adjacentplant cellsVacuolePlasmodesmata(channels between cells)
Animal Cell Surfaces and Cell JunctionsAnimal cells lack cell wallsThey secrete a sticky covering called the extracellular matrixThis layer helps hold cells together.
THE ORIGIN OF MEMBRANESPhospholipids were probably among the first organic molecules on the early Earth.
SUMMARY OF KEY CONCEPTSThe Two Major Categories of Cells.Visual Summary 4.1
Membrane Structure and FunctionA Fluid Mosaic of Lipids and Proteins.
Visual Summary 4.2Outside cellPhospholipidProteinHydrophilicHydrophobicHydrophilicCytoplasm (inside cell)